Electricity distribution system and electricity distribution method

ABSTRACT

An electricity distribution system includes an electricity supply control unit that receives information on power consumption, estimates the current and the future power consumption, and controls the supply of electricity to the electric device; an information display unit that displays information on a power use situation of an electric device electrically connected with the electricity supply control unit; and a battery server that accumulates power, in which the electricity supply control unit communicates the information on the power consumption with a new electric device when the new electric device is electrically connected, and when the amount of available power is exceeded by supplying electricity to the electric device, does not supply electricity to the electric device, makes the information display unit display that the amount of available power is exceeded by supplying electricity to the information display unit, and determines whether to use the power accumulated in the battery server.

CROSS REFERENCE TO PRIOR APPLICATION

This application is a continuation of U.S. patent application Ser. No.13/298,547 (filed on Nov. 17, 2011), which claims priority to JapanesePatent Application No. 2010-270439 (filed on Dec. 3, 2010), which areall hereby incorporated by reference in their entirety.

BACKGROUND

The present disclosure relates to an electricity distribution system andan electricity distribution method.

At present, power that an electric power company generates at a powerstation is transmitted to homes businesses, or the like through a publicpower wiring network. Homes and businesses contract with the electricpower company for the use of electricity and the power usage isdetermined on the basis of the contract. Further, for example, when theamount of current exceeds the amount determined by the contract with theelectric power company due to the simultaneous use of a plurality ofelectric devices in a home, a breaker trips to make electricityunavailable.

For example, a distribution board is installed in the home. Thedistribution board measures the amount of total current for each area ina plurality of areas in the home. Further, when the capacity isexceeded, the distribution board trips the breaker of the area where thecapacity is exceeded. Further, since the amount of total current in ahouse is measured, when the total capacity of the house is exceeded, thedistribution board trips a main breaker to stop the inflow of currentinto the entire house.

Therefore, when a microwave oven, an electric stove, a dryer, an airconditioner or the like, which consume a large amount of power, aresimultaneously used in a home, the amount of current may exceed theamount determined by the contract with the electric power company andthe breaker may trip.

SUMMARY

However, in an electricity distribution system of the related art, thereis a problem in that it is difficult to quantitatively ascertain howmuch power is currently used and to what extent which electric productsmay be used before the breaker trips. Accordingly, there is a problem inthat the user has to rely on their intuition as to whether the breakerwill trip or not.

For example, Japanese Unexamined Patent Application Publication No.9-84146 discloses a technology that uses a network and prevents abreaker from operating when a user freely turns on/off the appliances ina house without concern for the maximum power consumption determined bythe contract with the electricity power company. However, the technologydisclosed in Japanese Unexamined Patent Application Publication No.9-84146 merely outputs a warning message when the power consumption islikely to exceed, or has exceeded, a predetermined value, such that itis difficult to increase/decrease the power usage or automaticallycontrol electrically-connected electric devices.

It is desirable to provide a new and improved electricity distributionsystem and electricity distribution method that can ascertain how muchpower is currently used and to what extent which electric products maybe used before the breaker trips or that can measure anincrease/decrease in the amount of available power.

An electricity distribution system according to an embodiment of thepresent disclosure includes: an electricity supply control unit thatreceives information on power consumption from an electric device thatis electrically connected, estimates the current and the future powerconsumption, and controls the supply of electricity to the electricdevice; an information display unit that displays information on a poweruse situation of the electric device electrically connected with theelectricity supply control unit; and a battery server that accumulatespower, in which the electricity supply control unit communicates theinformation on the power consumption with a new electric device when thenew electric device is electrically connected, and when the amount ofavailable power is exceeded by supplying electricity to the electricdevice, does not supply electricity to the electric device, makes theinformation display unit display that the amount of available power isexceeded by supplying electricity to the information display unit, anddetermines whether to use the power accumulated in the battery server.

The electricity distribution system may further include acharging/discharging control unit that controls charging/discharging ofthe battery server, in which the electricity supply control unitcontrols the charging/discharging control unit to use the poweraccumulated in the battery server when determining that the amount ofavailable power is exceeded by supplying electricity to the electricdevice, as a result of communicating the information on the powerconsumption with a new electric device when the new electric device iselectrically connected.

The electricity supply control unit may communicate the information onthe power consumption with a new electric device when the new electricdevice is electrically currently connected, and start to supplyelectricity to a new electric device when the amount of available poweris not exceeded even though the power consumption of the electric deviceelectrically connected is decreased and electricity is supplied to thenew electric device, when the amount of available power is exceeded bysupplying electricity to the electric device.

The electricity supply control unit may communicate the information onthe power consumption with a new electric device when the new electricdevice is electrically connected, and perform control for decreasing thepower consumption of the electric device currently electricallyconnected, when the amount of available power is exceeded by supplyingelectricity to the electric device.

The battery server may accumulate power generated by a power generatorthat generates electricity, using natural energy.

A plurality of power generators may be included and the power generatorsmay each be equipped with a boosting device making the power generatedfrom the plurality of power generators uniform at predetermined power.

An electricity distribution method according to another embodiment ofthe present disclosure includes: receiving information on powerconsumption from an electric device that is electrically connected,estimating the current and the future power consumption, and controllingthe supply of electricity to the electric device; and displayinginformation that displays information on a power use situation of theelectric device electrically connected with the electricity supplycontrol unit; in which, in the controlling of the supply of electricity,the information on the power consumption is communicated with a newelectric device when the new electric device is electrically connected,and, when the amount of available power is exceeded by supplyingelectricity to the electric device does not supply electricity to theelectric device, displays that the amount of available power is exceededby supplying electricity in the displaying of information, anddetermines whether to use power accumulated in the battery server thataccumulates power.

According to the present disclosure described above, it is possible toprovide new and improved electricity distribution system and electricitydistribution method that can ascertain how much power is currently usedand to what extent which electric products can be used before that thebreaker operates or can measure an increase/decrease in the amount ofavailable power.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an illustrative diagram showing an exemplary configuration ofan electricity distribution system according to an embodiment of thepresent disclosure.

FIG. 2 is a diagram showing the flow of power of the electricitydistribution system according to an embodiment of the presentdisclosure.

FIG. 3 is a diagram showing the flow of power of the electricitydistribution system according to an embodiment of the presentdisclosure.

FIG. 4 is an illustrative diagram showing a graph for an example ofchanges in power consumption according to time passage in theelectricity distribution system according to an embodiment of thepresent disclosure.

FIG. 5 is an illustrative diagram showing an example of informationdisplayed on an interior display device.

FIG. 6 is a flowchart showing the operation of the electricitydistribution system according to an embodiment of the presentdisclosure.

FIG. 7 is an illustrative diagram schematically showing an electricitydistribution system of the related art.

DETAILED DESCRIPTION OF EMBODIMENTS

Hereinafter, preferable embodiments of the present disclosure will bedescribed in detail with reference to the accompanying drawings.

Further, in the specification and the drawings, like reference numeralsare given to components having substantially the same functionalconfiguration and repetitive description is not provided.

Further, description is provided in the following order.

<1. Electricity Distribution System of Related Art>

<2. Embodiment of Present Disclosure>

[2-1. Configuration of Electricity Distribution System]

[2-2. Operation of Electricity Distribution System]

<3. Conclusion>

1. Electricity Distribution System of Related Art

Problems of an electricity distribution system of the related art aredescribed first with reference to the drawings, before preferableembodiments of the present disclosure are described.

FIG. 7 is an illustrative diagram schematically showing an electricitydistribution system of the related art. The electricity distributionsystem of the related art includes, for example, a power meter 1010, adistribution board 1020, and an electric device 1040 operating inelectrical connection with a socket 1030. The electricity distributionsystem of the related art measures the amount of current of powersupplied from a public power distribution network 1, using thedistribution board 1020, and trips a breaker when the amount of currentflowing to a house exceeds a predetermined amount.

Meanwhile, the distribution board 1020 also has a function of measuringthe amount of total current for each of a plurality of areas in a home.Further, when the amount of total current of each of the area isexceeded the capacity set for each of the areas, only the breaker of thearea where the amount of total current is exceeded is tripped. In thiscase, the main breaker controlling the flow of current into the entirehouse is not tripped, but when a predetermined amount is exceeded as awhole, the main breaker trips even though the breakers of the areas donot trip.

However, as described above, in an electricity distribution system ofthe related art shown in FIG. 7, there is a problem in that it isdifficult to quantitatively ascertain how much power is currently usedand to what extent which electric products can be used before that thebreaker trips. Accordingly, there is a problem in that the user has torely on their intuition as to whether the breaker will trip or not.

Further, the electricity distribution system of the related art shown inFIG. 7 performs a process of unplugging the sockets and switching thebreaker, when the breaker trips. In this case, there is a problem inthat the electric devices with the power supply stopped are reset andthe content that is being processed is lost. For example, for amicrowave oven, when the breaker trips while food is being warmed, theup to date record of for how many minutes the food has been warmed forhow many watts is lost, such that it is difficult to continue the work.

In an embodiment of the present disclosure described below, an electricdistribution system that can quantitatively ascertain the present powerconsumption and allows a user to ascertain to what extent which electricproducts can be used before the breaker trips is described. Therefore,the user can ascertain to what extent which electric products can beused before the breaker trips, without relying on the user's intuition.

2. Embodiment of Present Disclosure 2-1. Configuration of ElectricityDistribution System

FIG. 1 is an illustrative diagram showing the configuration of anelectricity distribution system 10 according to an embodiment of thepresent disclosure. Hereinafter, an exemplary configuration of theelectricity distribution system 10 according to an embodiment of thepresent disclosure is described by using FIG. 1.

As shown in FIG. 1, the electricity distribution system 10 according toan embodiment of the present disclosure includes a power conditioner140, a battery server 150, an intelligent distribution board 160, aninterior display device 170, an operation board 171, a down-power meter180, an up-power meter 181, and smart sockets 190 a to 190 e.

Further, as shown in FIG. 1, the electricity distribution system 10according to an embodiment of the present disclosure includes solarcells 110 a and 110 b, another power generator 110 c, such as a windpower generator, boosting units 120 a, 120 b, and 120 c, a connectingunit 130, and electric devices 191 a and 191 b used in connection withthe smart sockets 190 a to 190 e.

The solar cells 110 a and 110 b are power generators that can generatepower by receiving light radiated from the sun. The power generated fromthe solar cells 110 a and 110 b is boosted to a predetermined voltage bythe boosting units 120 a and 120 b and transmitted to the connectingunit 130. Although two solar cells 110 a and 110 b are shown in FIG. 1,the number of solar cells is not limited to the example in the presentdisclosure. Further, the electricity distribution system 10 may not beprovided with a solar cell in the present disclosure.

Further, the electricity distribution system 10 according to anembodiment of the present disclosure, as shown in FIG. 1, may includeanother power generator 110 c using natural energy, such as wind powergeneration, different from the solar cell, (various energy sources thathave difficulty in maintaining the generation of constant power, such asmanpower power generation, are included in the “natural energy” of thepresent disclosure, without being limited to natural energy acquiredfrom solar light or wind force, and it is the same in the followingdescription). The power generated from the power generator 110 isboosted to a predetermined voltage by the boosting unit 120 c andtransmitted to the connecting unit 130. As energy generation sources,other than the solar cell, solar thermal power generation, a fuel cell,and manpower power generation (pedaling a bicycle or the like) may beconsidered in addition to the wind power generation.

In the power generated by the solar cells 110 a and 110 b, power abovethe usage is sold.

However, the user of the electricity distribution system 10 may not sellthe electricity depending on situation of the grid wiring network (forexample, a situation where the user purchases a predetermined amount ofpower and may not buy more than this) In this situation, powergeneration is stopped or the generated power is wasted in the relatedart. The power is accumulated in the battery server 150 in theembodiment.

The boosting units 120 a, 120 b, and 120 c boost voltage to apredetermined voltage to make the voltage of the power generated fromthe solar cells 110 a and 110 b and the power generator 110 c uniform.The power boosted to a predetermined voltage by the boosting units 120a, 120 b, and 120 c is transmitted to the connecting unit 130.

The connecting unit 130 collectively outputs the power transmitted fromthe boosting units 120 a, 120 b, and 120 c to the power conditioner 140.

The power conditioner 140 exchanges power with the battery server 150 orthe intelligent distribution board 160. The power conditioner 140 mayconvert the power from direct current into alternating current or fromalternating current to direct current, if necessary.

The battery server 150 is equipped with a battery (secondary battery)therein, such that it can be charged by the power generated from thesolar cells 110 a and 110 b, and a power generator 110 c or powersupplied from the public power wiring network 1. In order to charge thebattery server 150 with the AC power supplied from the public powerwiring network 1, the power conditioner 140 may convert alternatingcurrent into direct current and supply the electricity to the batteryserver 150.

Further, as an embodiment of the battery server 150, a device onlyequipped with a battery therein may be possible, and an electric vehicleor an electric motorcycle that can travel, using a battery as a powersource, may be possible. The electric vehicle or the electric motorcyclemay be used as a home battery server when it is not used.

Further, the battery server 150 may be charged with power at any timewhen it is possible to receive electricity from the public power wiringnetwork 1, or may be charged at a time, avoiding when most users usepower, for example, at night.

The intelligent distribution board 160 measures the power usage in ahome and the information on the power usage measured by the intelligentdistribution board 160 is appropriately notified to the interior displaydevice 170. Further, the intelligent distribution board 160 receivesinformation on the expected power consumption of electric devicesconnected to the smart sockets 190 a to 190 e, from the smart sockets190 a to 190 e. The intelligent distribution board 160 can output theinformation received from the smart sockets 190 a to 190 e to theinterior display device 170.

As described above, as the intelligent distribution board 160 acquiresthe information on the current power usage and the expected powerconsumption of the electric devices connected to the smart sockets 190 ato 190 e and transmits the acquired information to the interior displaydevice 170, the user can see the information displayed on the interiordisplay device 170 and quantitatively ascertain the current power usageand ascertain to what extent which electric product can be used beforetripping the breaker.

The interior display device 170 displays the information on the currentpower usage and the expected power consumption of the electric devicesconnected to the smart sockets 190 a to 190 e, which is transmitted fromthe intelligent distribution board 160. Information displayed by theinterior display device 190 is described in detail below.

Further, the intelligent distribution board 160 and the interior displaydevice 170 may be connected by a wire or wirelessly. Further, althoughit is described the display device that displays the information on thecurrent power usage and the expected power consumption of the electricdevices is installed in a house in the embodiment, the presentdisclosure is not limited to the example. The display device thatdisplays the information on the current power usage and the expectedpower consumption of the electric devices may be disposed outside.

The operation board 171 is provided, for example, integrally with theinterior display device 170 and gives an instruction of distributioncontrol to the intelligent distribution board 160. For example, whenelectric devices are connected to the smart sockets 190 a to 190 e andthe electric devices start to operate, and when the amount of power dueto the operation of the electric devices exceeds the amount of power inthe contract, the user operates the operation board 171 and can controlthe operation board such that supply of electricity from the intelligentdistribution board 160 is stopped in the electric system where theelectric devices are connected or such that power is output from thebattery server 150, when power is accumulated in the battery server 150.

Further, the operation board 171 may be implemented integrally with theinterior display device 170 by providing the interior display device 170with a touch panel function.

The down-power meter 180 is a meter that measures power transmitted fromthe public power wiring network 1. When the user uses power transmittedfrom the public power wiring network 1, the down-power meter 180performs a settlement process on the basis of the amount of powermeasured by the down-power meter 180.

The up-power meter 181 is a meter that measures power transmitted fromthe intelligent distribution board 160 to the public power wiringnetwork 1. When the user sells power by transmitting the power to thepublic power wiring network 1, a settlement process is performed on thebasis of the amount of power measured by the up-power meter 181.

The smart sockets 190 a to 190 e are sockets (plug receivers) having aninformation communication function, in addition to the general powersupply function, and can communicate information between the electricdevices and the intelligent distribution board 160 when thecorresponding electric devices are connected to the smart sockets 190 ato 190 e.

Further, it is preferable that the smart sockets 190 a to 190 e have ashape different from the existing sockets in order to prevent themistaken insertion of the plugs of electric devices that do notcorrespond to smart sockets. Further, in this configuration, thedetailed shape of the smart sockets 190 a to 190 e is not specificallystated.

Obviously, the smart sockets 190 a to 190 e may have a shape that canreceive insertion of the plugs of the electric devices that do notcorrespond to smart sockets. In this case, even if the plugs of theelectric devices that do not correspond to smart sockets are inserted inthe smart sockets 190 a to 190 e, information is obviously notcommunicated between the electric devices and the intelligentdistribution board 160.

Further, the plugs of the electric devices that do not correspond tosmart sockets may be inserted in the existing sockets (plug receivers).Even in this case, obviously, information is not communicated betweenthe electric devices and the intelligent distribution board 160.

The electric devices 191 a and 191 b are electric devices correspondingto smart sockets and it is possible to communicate information with theintelligent distribution board 160 by inserting the plugs into the smartsockets 190 a to 190 e.

The intelligent distribution board 160 automatically supplieselectricity to the electric devices 191 a and 191 b when it isdetermined that electricity can be distributed to the electric devices191 a and 191 b connected to the smart sockets 190 a to 190 e. However,when it is determined that power is insufficient, the intelligentdistribution board 160 warns of insufficient power through the interiordisplay device 170 and does not supply electricity to the electricdevices 191 a and 191 b connected to the smart sockets 190 a to 190 e.Further, when electricity is not supplied to the electric devices 191 aand 191 b connected to the smart sockets 190 a to 190 e, and when itbecomes possible to allow electricity to automatically flow to theelectric devices 191 a and 191 b after a predetermined time passes, itis notified when electricity can be supplied, through the interiordisplay device 170. When it becomes possible to automatically supplyelectricity to the electric devices 191 a and 191 b after thepredetermined time passes may be, for example, when a microwave ovenfinishes warming food or a washing machine finishes washing.

The information transmitted from the electric devices 191 a and 191 b tothe intelligent distribution board 160 may be, for example, informationon the operational states of the electric devices, other than theinformation on the expected power consumption described above. Theoperational state of the electric devices may be the time or the wattvalue taken to warm food, for example, when the electric device is amicrowave oven, or a situation in which washing is proceeding, forexample, when the electric device is a washing machine.

The configuration of the electricity distribution system 10 according toan embodiment of the present disclosure was described above. The flow ofpower in the electricity distribution system 10 according to anembodiment of the present disclosure shown in FIG. 1 is described.

FIG. 2 shows the flow of power when power generated from the solar cells110 a and 110 b or another power generator 110 c is output to the publicpower distribution network 1 to sell or be stored in the battery server150.

In the electricity distribution system 10 according to an embodiment ofthe present disclosure, it is possible to use an off-grid power systemusing natural energy, such as photovoltaic generation or wind powergeneration and accumulate a portion of remaining power in the batteryserver 150. Obviously, in the present disclosure, the entire powergenerated by the off-grid power system may be sold. Further, the batteryserver 150 may be charged with inexpensive night grid power.

FIG. 3 shows the flow of power when power supplied from a power stationthrough the public power wiring network 1 is supplied to the electricdevices 191 a and 191 b through the intelligent distribution board 160and the smart sockets 190 a to 190 e.

In the electricity distribution system 10 according to an embodiment ofthe present disclosure, it is possible to store the power, which issupplied from a power station through the public power wiring network 1,to the battery server 150. Obviously, in the present disclosure, thepower supplied from a power station through the public power wiringnetwork 1 may be supplied to the electric devices 191 a and 191 b,directly through the intelligent distribution board 160 and the smartsockets 190 a to 190 e. Further, the power may be supplied from thebattery server 150 to the electric devices 191 a and 191 b through thesmart sockets 190 a to 190 e, if necessary, when the contract powerconsumption is exceeded the expected power consumption.

The flow of power in the electricity distribution system 10 according toan embodiment of the present disclosure was described above. Next, theoperation of the electricity distribution system 10 according to anembodiment of the present disclosure is described in detail.

As described above, when electric products are connected to the smartsockets 190 a to 190 e, the expected power consumption is notified. Theintelligent distribution board 160 (or the power conditioner 140 or adevice integrally equipped with the power conditioner 140 and theintelligent distribution board 160) receiving the notificationcalculates the future expected power consumption and displays it on theinterior display device 170.

Meanwhile, when the electric devices are connected to not the smartsockets, but existing sockets, it is difficult to calculate the futureexpected power consumption, such that it is reflected in the futureexpected power consumption that the current power consumption ismaintained.

In the electricity distribution system 10 according to an embodiment ofthe present disclosure, a case where new electric devices that exceedthe contract power consumption are connected to the smart sockets 190 ato 190 e is considered. In this configuration, the display warns with asound or a screen. The warning says that when electricity is supplied tothe connected electric devices, the contract amount of power is exceededand the breaker trips as well as how long it will take to be able tosupply electricity.

In practice, although the contract amount of power consumption isexceeded at the present time, it may go under the contract amount afterwaiting for a predetermined time. For example, although a microwave ovenor an electric rice cooker consumes a large amount of power for a periodof time, generally, the power consumption is greatly reduced after theprocess is finished. When the process is finished, the contract powerconsumption may not be exceeded even if electricity is supplied to anewly connected device.

Meanwhile, nevertheless, in order to use the device, the poweraccumulated through the power conditioner 140 or directly to the batteryserver 150 may be used by an instruction from the user, or aninstruction is given in advance to the intelligent distribution board160 such that the power accumulated in the battery server 150 isautomatically used. As described above, since the power accumulated inthe battery server 150 is used, the user may be prevented from paying ahigh basic contract fee for using a large amount of power, which is madewith a power company.

Further, it may be possible to supply electricity to a newly connectedelectric device, by controlling the power consumption of otherelectronic devices. For example, it does not matter even if the powerconsumption is reduced by temporarily adjusting temperature or the like,for example, for a refrigerator or an air conditioner. For the devicesdescribed above, it may be possible to primarily distribute electricityto the connected devices by suppressing the power consumption for apredetermined time. This may be performed automatically or by a user'sinstruction.

FIG. 4 is an illustrative diagram showing a graph for an example ofchanges in power consumption according to time passage in theelectricity distribution system 10 according to an embodiment of thepresent disclosure. An electric device that consumes a large amount ofpower, such as a dryer, is connected to the smart sockets 190 a to 190e, for example, when the consumed power expectation measured by theintelligent distribution board 160 is under the contract powerconsumption. Further, when the expected power consumption is above thecontract power consumption by connecting the dryer, the intelligentdistribution board 160 does not supply electricity to the drier. This isbecause the power consumption is above the contract power consumptionand the breaker trips, due to connection of the dryer.

However, there may be an electric device that temporarily stops theoperation in the electric devices that are used now. For example, when amicrowave oven is used, food may be finished being warmed after severalminutes. In this case, when the operation of the microwave is finished,the power consumption correspondingly decreases, such that theintelligent distribution board 160 supplies electricity to the dryer atthis time point. Therefore, when the dryer is available, the user canuse the dryer without a specific operation.

Further, although the expected power consumption is above the contractpower consumption due to connection of the dryer, when the power of thebattery server 150 is used, the total amount of available powertemporarily increases, such that only the amount of power under thetotal amount of available power may be consumed, even though the dryeris connected. In this case, the intelligent distribution board 160supplies electricity to the dryer by controlling the power conditioner140 or directly using the power accumulated in the battery server 150.

As described above, the intelligent distribution board 160 ascertainsthe power consumption of the electric devices connected to the smartsockets 190 a to 190 e, and when electric devices are connected to thesmart sockets 190 a to 190 e, it determines whether to supplyelectricity to the connected electric devices from whether the powerconsumption is above the contract power consumption.

FIG. 5 is an illustrative diagram showing an example of informationdisplayed on an exterior display device 170. When sensing that a dryeris connected to the smart sockets 190 a to 190 e, the intelligentdistribution board 160 displays information on the interior displaydevice 170. As described above, when the information is displayed, itmay be notified with a sound.

A user of the electricity distribution system 10 operates the operationboard 171, if necessary, when receiving an instruction saying thatelectricity may not be supplied. In this case, it may be possible totransmit an instruction of supplying electricity, using the power of thebattery server 150. Further, it may be possible to create an instructionof supplying electricity by suppressing the power consumption of otherdevices. In the latter case, it may be possible to supply electricity toa desired device by adjusting the temperature of an airconditioner/refrigerator, the luminance of a television/lighting device,the operation speed of a washing machine, and the operation speed of thecharging of an electric vehicle. Further, it may be possible to instructthose in advance to be automatically processed. For example, it may bepossible to provide a setting for automatically using the power of thebattery server when power is insufficient, and nevertheless, ifinsufficient, adjusting the temperature of a refrigerator or an airconditioner, decreasing the luminance of a lighting device/television,and extending the charging process of an electric vehicle.

Next, the operation of the electricity distribution system 10 accordingto an embodiment of the present disclosure is described.

2-2. Operation of Electricity Distribution System

FIG. 6 is a flowchart showing the operation of the electricitydistribution system 10 according to an embodiment of the presentdisclosure. Hereinafter, the operation of the electricity distributionsystem 10 according to an embodiment of the present disclosure isdescribed by using FIG. 6.

The intelligent distribution board 160 estimates the present consumptionof power and the future consumption of power by ascertaining theoperation situations of the appliances 191 a and 191 b connected to thesmart sockets 190 a to 190 e (Step S101).

In Step S101, when the intelligent distribution board 160 estimates thepresent consumption of power and the future consumption of power, theintelligent distribution board 160 displays the estimated consumption ofpower on the interior display device 170 and the interior display device170 renews the display of the consumption of power (Step S102).

In Step S102, when the interior display device 170 renews the display ofthe consumption of power, the intelligent distribution board 160determines whether a new electric device corresponding to the smartsocket is connected to the smart sockets 190 a to 190 e (Step S103).

When a new electric device is not connected, as a result of thedetermination in Step S103, the process returns to Step S101 and theintelligent distribution board 160 continues estimating the presentconsumption of power and the future consumption of power. On the otherhand, when a new electric device is connected, as a result of thedetermination in Step S103, the intelligent distribution board 160communicates with the newly-connected electric device through a wire andacquires estimated power consumption from the electric device (StepS104).

In Step S104, when the intelligent distribution board 160 acquiresestimated power consumption from the newly-connected electric device,next, the intelligent distribution board 160 recalculates the futurepower consumption (Step S105).

Further, in Step S105, when the intelligent distribution board 160recalculates the future power consumption, the intelligent distributionboard 160 determines whether power is sufficient for the powerconsumption estimated in Step S105 (Step S106).

As the result of the determination in Step S106, when it is determinedthat the power is sufficient for the power consumption estimated in StepS105, the intelligent distribution board 160 supplies electricity to thenewly-connected electric device in Step S103 (Step S107) and the processreturns to Step S101. On the other hand, as the result of thedetermination in Step S106, when it is determined that the power is notsufficient for the power consumption estimated in Step S105, theintelligent distribution board 160 makes the interior display device 170displays a warning saying that the power is insufficient. The interiordisplay device 170 displays a warning saying that the power isinsufficient (Step S108).

In Step S108, when the interior display device 170 displays a warningsaying that the power is insufficient, next, the intelligentdistribution board 160 determines whether there is an instruction fromthe user by the operation board 171 (Step S109).

As the result of the determination in Step S109, when the operationboard 171 determines that there is no instruction from the user, theprocess returns to Step S105 and the intelligent distribution board 160recalculates the future power consumption. On the other hand, as theresult of the determination in Step S109, when the operation board 171determines that there is instruction from the user, next, theintelligent distribution board 160 determines whether to use the poweraccumulated in the battery server 150 (Step S110).

For whether to use the power accumulated in the battery server 150 whenit is expected that the power is insufficient, it may be set in theintelligent distribution board 160 to use the power accumulated in thebattery server 150 when it is expected that the power is insufficient inadvance, in which an instruction from the user may not be received inStep S109. Further, as shown in the embodiment, the user may be allowedto make an appropriate selection (Step S109) when it is expected thatthe power is insufficient.

As the result of the determination of Step S110, when it determined thatthe power accumulated in the battery server 150 is used, the intelligentdistribution board 160 corrects the amount of available power inconsideration of the power accumulated in the battery server 150 (StepS111).

In Step S111, when the intelligent distribution board 160 corrects theamount of available power in consideration of the power accumulated inthe battery server 150, next, it is determined whether the power issufficient for the corrected amount of available power (Step S112).

As the result of the determination in Step S112, when it is determinedthat the power is sufficient for the corrected amount of availablepower, power supply of the battery server 150 is started, electricity issupplied to the newly-connected electric device in Step S103 (StepS113), and the process returns to Step S101. On the other hand, as theresult of the determination in Step S112, when it is determined that thepower is not sufficient for the corrected amount of available power, orwhen it is determined that the power accumulated in the battery server150 is not used in Step S110, the intelligent distribution board 160reduces and recalculates the future estimated power consumption of theelectric device indicated from the user by the operation board 171 (StepS114). Further, the indicated electric device is an airconditioner/refrigerator, a television, a lighting device, a washingmachine, an electric vehicle, or the like.

In Step S114, when the intelligent distribution board 160 reduces andrecalculates the estimated future power consumption of the electricdevice indicated from the user by the operation board 171, next, it isdetermined whether the power is sufficient for the recalculatedestimated power consumption (Step S115). Further, the indication fromthe user may be provided in advance or may be performed every timeinsufficient power is ascertained.

As the result of the determination in Step S115, when it is determinedthat the power is sufficient for the recalculated estimated powerconsumption, the power consumption of the electric device indicated fromthe user (in advance) is reduced, and then, electricity is supplied tothe newly-connected electric device in Step S103 (Step S113), and theprocess returns to Step S101. On the other hand, as the result of thedetermination in Step S115, when the power is insufficient for therecalculated estimated power consumption, the process returns to StepS108, and the intelligent distribution board 160 makes the interiordisplay device 170 display a warning saying that the power isinsufficient and the interior display device 170 displays a warningsaying that the power is insufficient.

Further, all the electric devices (for example, electric devices A, B,and C) indicated (in advance) by the user are not necessarily objects,it may be possible to reduce the consumed power of the minimum necessarydevices (for example, only the electric devices A and B in the electricdevices A, B, and C) (reduced by 20% only for the electric devices A andB), or it may be possible to reduce the consumed power of all thedevices (for example, the electric devices A, B, and C) to the minimumnecessary (for example, reduced by 10% for the electric devices A, B,and C).

As described above, as the electricity distribution system 10 accordingto an embodiment of the present disclosure operates, it is determinedwhether power is sufficient within the amount of available power even ifpower is supplied to electric devices when electric devicescorresponding the smart sockets are connected to the smart socket 190 ato 190 e, and then, when the power is insufficient, an appropriatewarning is displayed or the consumed power of the electric devices thatare used now is reduced. Accordingly, it is possible to reduce theuser's burden by appropriately determining power excess and deficiency,which depends on the user's estimation or intuition in the related art.

Further, when electric devices that do not correspond to smart socketsare connected to the smart sockets 190 a to 190 e, the intelligentdistribution board 160 may temporarily supply electricity to thedevices, but may stop supplying electricity to a device which is foundto be exceeding the contract power consumption, and make the interiordisplay device 170 display a warning to this effect. Alternatively, theintelligent distribution board 160 may input the actual powerconsumption to the user and calculate the expected power consumptionfrom the value, every time electric devices that do not correspond tothe smart sockets are connected to the smart sockets 190 a to 190 e.

3. Conclusion

As described above, according to the electricity distribution system 10of an embodiment of the present disclosure, the intelligent distributionboard 160 keeps calculating the present power consumption and the futurepower consumption. Further, when electric devices corresponding to smartsockets are connected to the smart sockets 190 a to 190 e, theintelligent distribution board 160 determines whether the amount ofavailable power will be exceeded by supplying electricity tocorresponding electric devices.

Further, when the amount of available power is not exceeded even ifpower is supplied to the corresponding electric devices, the intelligentdistribution board 160 keeps supplying electricity to the correspondingelectric devices, and when the amount of available power is exceeded bysupplying the electricity to the corresponding electric devices, theintelligent distribution board 160 does not supply electricity to thecorresponding electric devices or temporarily increases the amount ofavailable power by using the power of the battery server 150, orsupplies electricity to the corresponding electric device when theamount of available power is not exceeded even if electricity issupplied to the corresponding devices.

Accordingly, the electricity distribution system 10 according to anembodiment of the present disclosure can reduce the user's burden byappropriately determining power excess and deficiency, which depends onthe user's estimation or intuition in the related art. Further, there isa problem in an electricity distribution system of the related art inthat the breaker is forced to trip when the amount of available power isexceeded and the electric devices with the power supply stopped arereset, such that the records that are being processed are lost. However,in the electricity distribution system 10 according to an embodiment ofthe present disclosure, since it is determined whether the amount ofavailable power will be exceeded, before supplying electricity, it ispossible to avoid the problem that the electric devices with the powersupply stopped are reset, such that the records that are being processedare lost.

It should be understood by those skilled in the art that variousmodifications, combinations, sub-combinations and alterations may occurdepending on design requirements and other factors insofar as they arewithin the scope of the appended claims or the equivalents thereof.

What is claimed is:
 1. An electricity distribution system comprising: acontrol unit that receives information on power consumption from anelectric device that is electrically connected, and estimates futurepower consumption; an information display unit that displays informationon a power use situation of the electric device electrically connectedwith the control unit, wherein the control unit communicates theinformation on the power consumption with a new electric device when thenew electric device is electrically connected, and when the amount ofavailable power would be exceeded by supplying electricity to theelectric device, makes the information display unit display that theamount of available power is exceeded by supplying electricity to theinformation display unit.
 2. The electricity distribution systemaccording to claim 1, further comprising a battery server thataccumulates power.
 3. The electricity distribution system according toclaim 2, wherein the battery server accumulates power generated by apower generator that generates electricity, using natural energy.
 4. Theelectricity distribution system according to claim 3, wherein aplurality of power generators is included and the power generators areeach equipped with a boosting device making the power generated from theplurality of power generators uniform at predetermined power.
 5. Theelectricity distribution system according to claim 2, further comprisinga charging/discharging control unit that controls charging/dischargingof the battery server, wherein the control unit controls thecharging/discharging control unit to use the power accumulated in thebattery server when determining that the amount of available power wouldbe exceeded by supplying electricity to the electric device, as a resultof communicating the information on the power consumption with the newelectric device when the new electric device is electrically connected.6. The electricity distribution system according to claim 2, wherein,when the amount of available power would be exceeded by supplyingelectricity to the electric device, the control unit further determineswhether to use the power accumulated in the battery server.
 7. Theelectricity distribution system according to claim 1, wherein thecontrol unit communicates the information on the power consumption withthe new electric device when the new electric device is electricallyconnected, and when the amount of available power would be exceeded bysupplying electricity to the electric device, starts to supply power tothe new electric device when the amount of available power is notexceeded even though the power consumption of the electric devicecurrently electrically connected decreases and electricity is suppliedto the new electric device.
 8. The electricity distribution systemaccording to claim 1, wherein the control unit communicates theinformation on the power consumption with the new electric device whenthe new electric device is electrically connected, and performs controlfor decreasing the power consumption of the electric device currentlyelectrically connected, when the amount of available power would beexceeded by supplying electricity to the electric device.
 9. Theelectricity distribution system according to claim 1, wherein thecontrol unit further controls a supply of electricity to the electricdevice.
 10. The electricity distribution system according to claim 9,wherein, when the amount of available power would be exceeded bysupplying electricity to the electric device, the control unit furtherdoes not supply electricity to the electric device.
 11. An electricitydistribution method comprising: receiving information on powerconsumption from an electric device that is electrically connected, andestimating future power consumption; and displaying information on apower use situation of the electrically connected electric device,wherein the information on the power consumption is communicated with anew electric device when the new electric device is electricallyconnected, and when the amount of available power is exceeded bysupplying electricity to the electric device, a notification isdisplayed indicating that the amount of available power would beexceeded by the supplying of electricity in the displaying ofinformation.
 12. The electricity distribution method according to claim11, further comprising accumulates power in a battery server.
 13. Theelectricity distribution method according to claim 12, wherein theaccumulated power is generated by a power generator that generateselectricity, using natural energy.
 14. The electricity distributionmethod according to claim 13, wherein the accumulated power is generatedby a plurality of power generators, and the power generated from theplurality of power generators are made uniform at predetermined power.15. The electricity distribution method according to claim 12, furthercomprising a controlling of charging/discharging of the battery server,wherein the power accumulated in the battery server is used whendetermining that the amount of available power would be exceeded bysupplying electricity to the electric device, as a result ofcommunicating the information on the power consumption with the newelectric device when the new electric device is electrically connected.16. The electricity distribution method according to claim 12, wherein,when the amount of available power would be exceeded by supplyingelectricity to the electric device, a determination is made as towhether to use the power accumulated in the battery server.
 17. Theelectricity distribution method according to claim 11, wherein theinformation on the power consumption is communicated with the newelectric device when the new electric device is electrically connected,and when the amount of available power would be exceeded by supplyingelectricity to the electric device, power is started to be supplied tothe new electric device when the amount of available power is notexceeded even though the power consumption of the electric devicecurrently electrically connected decreases and electricity is suppliedto the new electric device.
 18. The electricity distribution methodaccording to claim 11, wherein the information on the power consumptionis communicated with the new electric device when the new electricdevice is electrically connected, and a control for decreasing the powerconsumption of the electric device currently electrically connected isperformed, when the amount of available power would be exceeded bysupplying electricity to the electric device.
 19. The electricitydistribution method according to claim 11, further comprisingcontrolling a supply of electricity to the electric device.
 20. Theelectricity distribution method according to claim 19, wherein, when theamount of available power would be exceeded by supplying electricity tothe electric device, the electricity is controlled so as to not besupplied to the electric device.
 21. A non-transitory computer-readablemedium having embodied thereon a program, which when executed by acomputer, causes the computer to perform an electricity distributionmethod, the method comprising: receiving information on powerconsumption from an electric device that is electrically connected, andestimating future power consumption; and displaying information on apower use situation of the electrically connected electric device,wherein the information on the power consumption is communicated with anew electric device when the new electric device is electricallyconnected, and when the amount of available power is exceeded bysupplying electricity to the electric device, a notification isdisplayed indicating that the amount of available power would beexceeded by the supplying of electricity in the displaying ofinformation.